Scale



Jan. 5, 1937. J. 'w BRYCE 2,066,762

' SCALE Filed July 12, 1933 7 Sheets-Sheet 1 [E cl 8 (D m o J O Llo 9 INVENTOR g g Y m g ATTORNEY J. W. BRYCE Jan. 5, 1937.

S GALE 1933 7 Sheets-Sheet 2 Filed July 12 ATTORNEY wow :u

Jan. 5, 1937. l w, BRYCE 2,066,762

SCALE Filed July 12, 1935 7 Sheets-Sheet s INVENTO g g WO RNEY J. W. BRYCE Jan. 5, 1937.

SCALE 7 Sheets-Sheet 4 Filed July 12 1933 INVENTOR [111m mum g mmm WWW ATTORNEY Jan. 5, 1937.

SCALE 7 Sheets-s Filed July 12 1933 |NVENTOR W a NQN m3 wow N2 ga s mm? ONV. V

WNV mmv/ mTmv omwLm Gm NW N r Aww mmm Q8 .0

ATTORNEY TEA/5 Jan. 5, 1937. 2,066,762

J. w. BRYCE SCALE Filed July 12, 1953 7 Sheets-Sheet 6 J. W. BRYCE Jan. 5, 1937.

SCALE Filed July 12, 1955 v 7 Sheets-Sheet 7 EN Mmv BUG UN INVENTOR Y J, ATTORNEY 222 52: wQV

Patented Jan. 5, 1937 UNITED STATES PATENT OFFICE SCALE Application July 12, 1933, Serial No. 680,025

39 Claims.

This invention relates to weighing scales and more particularly to scales of the factor lever type, including a mass sensing device.

One object of the present invention is to provide a scale of the offset weight type in which the offset weights are not applied until after the load is sensed or weighed.

Another object is to provide a mass sensing device in which the sensing of the digital values for different denominational orders is substantially concurrent.

Another object is to provide a weighing scale in which the setting up of sensed values is effected electrically so that there is no reactive effeet on the weighing mechanism.

Still another object is to provide a weighing scale in which the application of offsetting weights is accomplished simultaneously with the sensing of the weight values.

A further object is to provide a weighing scale with means to change the ratio of a lever system for weighing to a plurality of denominational rders.

Another object is to provide a weighing scale with a novel signal to indicate the condition of the scale.

Another object is to provide a weighing scale with a novel indicating and recording mechanism which may be located remotely from the scale.

Still another object is to provide a weighing scale with novel sensing means and with a novel system of levers whereby a small portion of the load is distributed equally to each of the sensing means.

Another object is to provide a weighing scale with an indicating mechanism adapted to be reset under the control of the scale.

Various other objects and advantages of my invention will be obvious from the following particular description of one form of mechanism embodying the invention or from an inspection of the accompanying drawings, and the invention also constitutes certain new and novel features of the construction and combination of parts hereinafter set forth and claimed.

In said drawings:

Fig. 1 is a view in front elevation of the scale having the indicating and recording mechanisms superimposed thereon.

Fig. 2 represents the indicating and recording mechanisms removed from the scale but operatively connected thereto by a flexible cable of indeterminate length.

Figs. 3 and 3a taken together illustrate the factor levers, the sensing means, the oiT-setting weights and the ratio adjusting means.

Fig. 4 is a sectional view taken through the indicating and recording mechanisms.

Fig. 5 is a top plan view of the indicating and recording mechanisms with the machine casing broken away for clearness.

Fig. 6 is a detail view showing the indicator, printer and punch operating clutch and the resetting clutch.

Fig. 7 is a detail view of the indicator alining device.

Fig. 8 is a detail view of the indicator reset overthrow means.

Fig. 9 is a detail view of the scale balance indicator.

Fig. 10 is a fragmentary detail sectional view General description Described in general terms the scale forming the subject matter of the instant invention includes the usual load support connected through a system of levers to a balancing lever and to a system of ratio changing levers. These levers deliver a small portion of the load to a system of factor levers which in turn distribute equal portions of the load to a plurality of sensing levers there being a sensing lever for each digital order from 0 to 9 inclusive. The sensing levers are counter balanced by successively greater weights so that when a load is placed on the support the sensing levers will be unbalanced up to and including the highest digital order represented by the load.

Mechanism is provided to sense successively a plurality of denominational orders. For instance, if a weight of 564 units be placed on the support the scale will sense first the 500 hundreds, then the sixty tens and finally the 4 units,

the sensing being accomplished in successive cycles of a weighing operation. Each weighing operation comprises a definite number of cycles. In the illustrative embodiment of the invention provision is made to weigh to three denomination orders but it is to be understood that it is not intended to limit the invention to weighing masses to any given number of denominational orders since by making certain obvious changes the number of denominational orders to which the scale will respond may be varied without departing from the spirit of the invention.

The first weighing cycle senses for hundreds of units which may be pounds, pounds and tenth c0 of pounds, pounds and ounces, etc. The second cycle senses for tens of units of weight, and the third cycle senses for units, which successive sensing will be more fully brought out later.

The scale is automatic and, as soon as a load is placed on the load support the lowest or 0 digital sensing lever is unbalanced and initiates a cyclic operation of the weighing out mechanism. During the first cycle the load is applied to the sensing levers in equal portions through a lever system having a certain ratio between the load support and the sensing levers. The sensing devices automatically control mechanism to offset the hundreds of units of weight but leaving the scale unbalanced by the tens of units and units of weight of the load. Late in the first cycle the ratio of the lever system is changed and the operating mechanism proceeds into the second or tens cycle.

During the second cycle the same sensing operation is made but since the hundreds of units of weight was balanced oil and the lever ratio changed the tens of units of weight is now read out. At this cycle the tens of units of weight are automatically offset in addition to the hundreds of units of weight offset at the first cycle, thus leaving the scale unbalanced by the weight represented by the units denominational order. Later in the second cycle the ratio of the lever system is again changed and at the third cycle the remaining unbalanced weight represented by the units denominational order is sensed and this weight automatically offset leaving the scale exactly in balance.

The machine stops when the scale is in balance and the operator may operate the printing and punching devices, after which the load is removed from the support, again throwing the scale out ofbalance. This initiates a reset operation during which the indicators, printing wheels and the punch selectors are restored to zero, the offset mechanism is operated to bring the scale into balance and the lever system is restored to its original condition. The scale is now in condition to proceed with another weighing operation.

In Figure 1 the scale is shown encased in the conventional casing 20 with the indicating and recording mechanisms mounted on top and enclosed in a casing 2 I. It is to be understood that the indicating and recording mechanism may be located remotely from the scale proper since it is connected thereto only by a cable connection 22 as illustrated in Figure 2.

The scale-lever system Referring to Figures 3 and 3a, a weighing load is placed on a suitable load support 23. The action of the load is transmitted to a link 24 through the intermediary of any convenient transmitting system. The system chosen for illustrative purposes includes levers 25 and 26 pivotally supported on uprights 21 and 28 respectively. The platform 23 rests on a traverse 29 having pivots 30 projecting therefrom supported in loops 3| and 32 suspended respectively from pivots 33 and 34 on the 1evers'25 and 26. The free end of the lever 25 is supported by a loop 35 depending from a pivot 36 on the lever 26 and the free end of the lever 26 transmits the action of the load to the link 24.

At its upper end the link 24 is supported on a pivot 31 projecting from the lower end of a short link 38 which has its upper end supported on a pivot 39 projecting from the center of a horizonta-l lever 40. The pivot 31 in the link 30 also cooperates with a weight ofiset lever 4| fulcrumed at 42 on a fixed support 43. Various combinations of offset weights may be applied to points 44, 45, and 46 on the lever 4| as will be more fully explained later. A weight 41 is adjustably supported on the right hand (Fig. 3a) end of the lever 4| to balance the weight of the lever itself.

The right hand end of the lever (Fig. 3a) is suspended on a pivot 49 carried by a link 50 having its upper end supported on a pivot 56 projecting from the middle of a lever 51. The right hand end of this lever is supported by a pivot 50 in the lower end of a link 59 depending from a pivot 60 in a lever 6| fulcrumed at 62 on a fixed support 63. The left hand end of lever 51 is supported on a pivot 64 in a link 65 depending from a pivot 66 in the lever 6|.

The left hand end (Fig. 3a) of the lever 40 is pivotally supported at 61 to a link 69 having its upper end normally supported at 69 on one end of a pair of levers 10, one disposed on each side of the link 68. These levers 10 have a fixed pivot 1 I and are adapted to be rocked in a manner to be described later by a magnet 12. The left hand end of the lever 6| is pivotally connected at 13 to a link 14 depending from a pivot 15 projecting from the mid-point of a horizontal lever 16.

The load applied to the support or platform 23 is applied through the lever system just described to the link 14, and is then split up and distributed in equal portions to a plurality of sensing levers 80, 8|, 92, 93, 94, 85, 86,91, 88, and 89 corresponding to the digits 0 to 9" inclusive. The sensing levers and weight distributing levers are counterbalanced by weights 90, 9|, 92, 93, 94, 95, 96, 91, 90, and 99 respectively of increasing increments of weight. The weight 90 for the 0" lever 80 is just suflicient to counterbalance the lever 80 plus its share of the weight of the distributing levers and the weight 9| for the "1" lever equals the 0 weight plus one unit of weight. The 2 weight equals the 0 weight plus two units of weight, etc., to the 9" weight 99 which equals the 0 weight 90 plus nine units of weight.

The sensing levers 80 to 89 inclusive are mounted by pivots I00 on fixed supports I0l. Eachof the sensing levers receives its portion of the load from the link 14 through the following described system of levers.

The left hand end (Fig. 3) of the lever 16 is pivotally connected by a link I06 to a lever 01 which lever I01 has its left hand end pivotally connected by a link I00 to the mid-point of a lever I09. The right hand end of the lever I01 is pivotally supported on a vertically disposed link H0. The left hand end of the lever I09 is connected by a link III to the center of a lever II2 having its left hand end connected by a link II3 to the 0 sensing lever 80 and having its right hand end connected by a link M4 to the 1 sensing lever 8|. The right hand end of the lever I09 is connected by a link II5 to the midpoint of a lever I I6 having its left hand end connected by a link II1 to the 2 sensing lever 82 and its right hand end connected by a link H0 to the 3 sensing lever 83.

The link H0 is supported at its upper end at the mid-point of a lever 9 having its left hand end connected by a link I20 to the 4" sensing lever 04 and its right hand end connected by a link I2I to the 5 sensing lever 85.

The right hand end of the lever 16 is conleft hand connected to the lower nected by a link I22 to a lever I23 having its end of the link H0 and its right hand end connected by a link I24 to the mid-point of a lever I25. The left hand end of the lever I25 is connected by a link I26 to the centre point of a lever I21 and the right hand end of said lever I25 is connected by a link I28 to the centre point of a lever I29. The lever 121 is connected at its left and right hand ends by links I30 and BI to the 6 and 7 sensing levers'86 and 81 respectively. The left and right hand ends of the lever- I29 are connected by links I32 and I33 respectively to the 8 and 9 sensing levers 88 and 89.

The pivots I34 and 135 connecting the links I06 and I22 respectively to the levers I01 and I23 are located at points one-fifth the length of these levers from the outer ends thereof giving these levers a ratio of 1 to 4. Assuming that a load of 10 units of weight is applied to the lever 16 by the link 14, this weight will be distributed equally to all of the sensing levers. each sensing lever receiving a load of one unit of weight.

The ten-unit load applied to the lever 16 is split, one-half or five units being applied by the link I06 to the lever I01, and one-half or five units being applied by the link I22 to the lever I23. The levers I01 and I23 having a ratio of 1 to 4 deliver four units to the levers I09 and I25, and each of the levers I01 and I23 deliver a load of one unit of weight to the link IIO making the total load applied by said link IIO to the'lever I19 two units.

The loads applied to the levers I09 and I25 are again split applying two units of weight to each of the levers H2, H6, I21, and I29. Each of these latter levers, including the lever H9, now has a load of two units of weight applied thereto. These loads are again split and a load of one unit of weight is applied by the links H3, H4, I11, H8, I20, IN, I30, I3I, I32, and I33 respectively to the sensing levers to 89 inclusive. Thus it can be seen that any weight applied to the lever 16 is distributed in equal portions to the ten sensing levers 80 to 89 inclusive.

As stated above, the weights to 99 inclusive are of increasing increments of weight. Since 'the weight 90 on the 0 sensing lever 80 is just suflicient to keep it in balance it is obvious that any weight applied to the scale will unbalance this lever 80, but if one-tenth of the load applied to the lever 16 through the medium of the link 14 and the factor lever system is greater than the weight of the counterbalance 9| on the 1 sensing lever 8|, this lever becomes unbalanced. Similarly if the loads applied to the levers 80 to 89 inclusive lies between the weights of the counterbalances 92 and 93 the 2 sensing lever 82 will be unbalanced but the levers 83 to 89 inclusive will remain in balanced condition. Obviously, therefore, all of the sensing levers whose counterbalances are of less weight than the load applied thereto will be unbalanced, and those sensing levers whose counterbalances are of greater weight than the load applied thereto will remain in balanced condition.

Associated with the sensing levers 80 to ,89 inclusive are levers I40 to I49 respectively. These levers have one of their ends in contact with their corresponding sensing levers and their opposite ends adjacent a series of contacts I 50 to I59 respectively associated with the several dig- 3 ital sensing levers. Closing the 0 contacts I50 efi'ects cyclic operation of the scale and of the indicating mechanism as will be more fully described later. The contacts I51 to I59 inclusive read off the amount of the weight under the control of the sensing levers.

Ofisetting weights It was stated above that-a weighing operation requires three cycles to weigh out to three denominational orders. During these cycles of operation certain things are automatically efiected among which is the selective application of weights either singly or in combination to the oflset weight lever M (Fig. 3a) under the control of the sensing devices and suitable commutators, to offset that portion of the load weighed out during that particular cycle. For instance, if a load of 462 units of weight be placed on the support 23, the lever 4I will be unbalanced to the full extent of the load. After the hundreds order, which in the example cited will be 400, is sensed and indicated, it is necessary to offset this 400 units of weight on the offset lever 4i by applying offset weights of the proper value and at the proper point on the lever 45. The several points 44, 45, and 46 of oifset weight application on the lever U have definite ratios to the fulcrum 42 of the lever and the point 31 of load application, consequently the offset weights applied at these points may be accurately computed and need be of but a small fraction to the load itself.

Depending respectively from the points it, 45, and 46 of the lever 4! (Fig. 3a) are rods I66, I51, and I68 each of which is provided with a plurality of offset weight supports I69, the lower one of said supports being retained by suitable nuts.

Associated with the weight rod I66 is a series of offset weights I10, I11, I12, and I16. These weights are adapted to be called either singly or in combination in a manner to be described later in connection with the description of the electrical circuits. Similarly weights I16, I15, I16, and I11, are associated with the rod I61, and weights I18, I19, I80, and I81 are associated with the rod I 60.

The following chart lists the values in units of weight of the ofisetting weights both singly and in combinations:

Combinations Value in units of Hundreds Tens Units weight 170-100 -170 10-174 1-178 171-200 200-172 20-176 2-180 172-200 300-l70+l72 30-174-1-176 3-178-1-180 173-400 400-173 40-177 1-181 174-10 500-+l73 50-174-1-177 5-178-H81 175-20 600-172+173 60-170+l77 6-18J+18l 176-20 700-l70+l72+173 70-174+l76+l77 7l78+l80+l8l 177-40 800-171-1-172-1-173 80-l75+176+l77 8l79+l80+181 178-1 900-l70+171+l72 90-174+175+17ri 9-178-I-17SH-l80 In the example given above, namely that of weighing a load of 462 units of weight the load would be balanced oil? as follows: During the first cycle the 400 units of weight, which is sensed at this cycle, is balanced by applying weight I13 to the lever M at point 44. The scale is still unbalanced by the remaining load of 62 units of weight.

' this ratio is 1 t 2.

During the second cycle the 60 units of weight are sensed and mechanism to be described later is controlled to apply weights I16 and I11 to the point 45 on the lever H to balance off the 60 units of weight. At the third cycle the units of weight, 2 units in this example, is sensed and the weight I88 applied at the point 46 on the lever 4I. Thus it may be seen that the load of 462 units of weight is balanced by the weights I18, I16, I11, and I88 totaling 462 units of weight and since at the end of a weighing operation this load is balanced by the weights applied to the lever 4I, none of the load is applied to the lever system at the point 89. The scale is now said to be in balance.

The selection of the hundreds weights I18, I1I, I12, I18 is efiected by magnets I82, I83, I84, and I85 respectively. Energization of one of the magnets rocks its armature I86 counterclockwise about its pivot I81 against the tension of a spring I88. The armature I86 is operativeiy connected to a pair of levers I89 (only one being shown herein) embracing the weight associated therewith, said levers I89 being pivotally supported by a bar I98. The levers I89 are notched to receive pivots I9I one projecting from each side of each weight but only one appearing in the drawings.

The springs I88 are of suillcient tension to hold the armatures I86 at the limit of their clockwise movement which is limited by the pin and slot connection between the armatures and their levers I89, thus holding the weights free of the supports I69.

Upon energization of one of the magnets I82 to I85 inclusive it rocks the associated armature I83 counterclockwise and rocks the levers I89 clockwise thus lowering the particular weight I18 to I13 inclusive onto its support I69 on rod I66. The movement of the lever is sufllcient to clear the pivots I9I permitting the entire weight to be applied to the rod I66.

The tens weights I14 to I11 are controlled respectively by magnets I92 to I95 inclusive and the units weights I18 to I8I are controlled respectively by magnets 28I to 284 inclusive. The armatures I86, springs I88 and levers I89 for the tens weights and for the units weights are similar to those parts associated with the hundreds weights and have therefore been given the same reference numerals.

Ratio lever system In addition to selectively applying the ofiset weights the ratio of the lever system 48, 51, and BI (Fig. 3a) is changed twice during the three cycles of a weighing operation. The ratio of this lever system between the points 89 and 18 during the first cycle, when weighing out the hundreds of weight units, is 1 to 200. Near the end of the first cycle this ratio is changed to 1 to 20 and near the end of the second cycle the ratio is again changed so that during the third cycle when the units of weight is weighed out The ratio of this lever sys- 1 to 200 ratio during the for the next succeeding tem is restored to the reset cycle in readiness weighing operation.

At the beginning of a weighing operation the ratio of the lever system 48, 51, 6I is therefore 1 to 200, that is, the application of 200 units of weight to the point 89 will result in the application of 1 unit of weight to the point 18. Onehalf of the load applied to the lever 48 is applied to the point 49 and also the fulcrum 56 of the lever 51, and one-half is applied to the point 61. During the first cycle, however, the point 61 forms 9. since at this time the link 68 is supported by the lever 18. That part of the load applied to 49 and 56 is active to effect the weighing. The lever 61 evenly divides the load applied to its fulcrum 56, applying half of such load to each of the pivots 58 and 64, and by the links 59 and 65 to the pivots 68 and 66 on the lever 6i. The fulcrum 56 of the lever 51 is offset to the left (Fig. 3a) of the fulcrum 62 of the lever 6| 9. distance equal to one one-hundredth of the distance from the fulcrum 62 to the point 18. This makes the effective ratio of the lever 8| from the points 62 to 56 and from 62 to 18 equal to 1 to 100 during the first cycle while weighing the hundreds of units of weight.

The ratio of the lever system is changed near the end of the first cycle by the energization of a magnet 285. The armature 286 of this magnet is pivoted at land is secured to a pair of levers 288 (only one being shown) each of which levers have notches in the upper edges thereof to receive projections 289 on the link 59 and 2I8 on a counterbalance 2 adapted to be applied to the lever H at a point 2I2. A spring 2I8 normally holds the levers 288 and the armature 286 in retracted position, but upon 'energization of the magnet 285 (in a manner to be described later) the armature 286 and the levers 288 are rocked clockwise (Fig. 3a) raising the link 58 out of contact with the pivot 68 and applying the counterbalance 2 to the point 2I2 on the lever 6|. The purpose of the counterbalance 2 is to compensate for the weight of the link 59 and its attached parts when this link is lifted free of pivot 68.

Raising the link 58 establishes a fixed pivot at 58 for the lever 51, consequently only one half the load applied at 56 is now, at the second cycle, effectively applied to the lever H at 66. The ratio of the lever 6I between pivot points 66 and 18 is l to 5, and the resultant ratio between the points 89 and 18 is 1 to 20. As was stated above, weighing a mass of for instance 222 units of weight, the 200 weight units are balanced off during the first cycle by automatically applying the proper weight or weights to the point 44 of lever 4I thus leaving the 22 weight units effective during the second cycle. Assuming then that a load of 22 weight units is applied to the point 89, the point 56 will receive 11 units while but 5.5 units is applied to the points 64 and 66, and, since the ratio of the lever 6I is now to l a load of 1.1 weight units is applied to the point 18.

During the second cycle when weighing the tens of weight units the weight units are balanced by automatically applying the proper offset weight or weights to the point 45 on the lever 4I, thus leaving a mass of 2 weight units applicable to the point 89 during the third cycle.

Near the end of the second cycle another change in ratio of the lever system occurs automatically. This time the ratio between the points 89 and'18 is 1 to 2, consequently the 2 units of weight applied to 88 is reduced to 1 unit of weight at the point 18. This change in ratio is effected in the following described manner: A pair of levers 2I4 (Fig. 341) (only one .being shown), secured together and secured to an armature 2I5 of a magnet 2I6 is pivoted at 2". A spring 2I8 normally holds the levers 214 in fixed pivot for the lever 48 the position in which they appear in Figure 3a. Projections 2! 9 on a counterbalance 226 rest in notches in the levers 2!4 supporting the counterbalance 226 clear of projections 22! on the lever 6!.

The opposite ends of the levers 2!4 are normally clear of projections 222 on the link 65 but are adapted, upon energization of the magnet 2! 6 to contact the projections 222 and raise the link 65 clear of the projection 66 on the lever 6!. The counterbalance 226, whose purpose is to compensate for the weight of link 65 and its attached parts when this link is lifted free of pivot 66, is simultaneously applied to the lever 6! at the point 22!.

Simultaneously with the energization of the magnet 2!6, the previously described magnet 12 is energized rocking its armature 223 together with the levers 16 counterclockwise rendering the link 68 effective to couple the lever 46 directly to the link 14. At their counterclockwise movement the levers 16 also contact projections 224 on a counterbalance 225 normally applied at a point 23! to the lever 6!, raising this counterbalance free of the lever 6!. The purpose-of the counterbalance 225 is to compensate for the weight of link 68 and its attached parts when this link is lifted free of pivot 13.

The links 59 and 65 are now supported by the levers 268 and H4 respectively thus providing a fixed pivot at 49 for the lever 46 thus one-half of the load of 2 weight units applied at 39 is now applied at 61 and 13. At the third cycle the lever 6! fulcrumed at 62 is counterbalanced by the weights 2!! and 226 and is ineffective to transmit any portion of the load applied to 36.

The magnets 265, 2!6, and 12 which control the changing of ratios, and the magnets which select the offset weights remain energized until a resetting operation occurs following a weighing operation. A descriptionof a reset operation will be given later.

Indicating and recording mechanism It is desired to indicate, as well as to print and punch the weights in three denominational orders. Two groups of three indicator wheels are provided, one group visible toward the front of the machine and the other group visible toward the rear of the machine. The three indicator wheels represent three denominational orders of weight units, that is, hundreds, tens and units, one denominational order wheel being set at each of the three cycles of a weighing operation.

It may be stated here that by changing the proportions of the offsetting weights the scale may be made to weigh in tens, units and tenths of weight units or, units, tenths and hundredths of weight units all of which weights may be indicated on the indicating mechanism now to be described.

Referring to Figure the two groups of indicator wheels are designated as follows: Front indicators, hundreds order 232, tens 233, units 234. Rear indicators hundreds order 235, tens 236 and units 231. It may be seen that the order of the rear indicator wheels is reversed to that of the front so that the numbers displayed toward the rear will read in their proper denominational order. The indicators 232. 233 and 234 are rotatably mounted on a shaft 238 supported by a bracket 233 and a cross frame 246 extending between two frames 24! and 242 suitably mounted on a base not shown).

Gears 243. one secured to the side of each of an impulse emitter 258 (see the indicator wheels, mesh with gears 244 rotatably mounted on an indicator drive shaft 245 supported in the frame 246, in a bracket 246 secured to the frame 24!, and in a cross frame 241. Integral with each of the gears 244 is a clutch member 248 adapted to be engaged by a companion clutch member 249 mounted to rotate with but slidable longitudinally on the shaft 245. The members 249 are shifted into engagement with 248 by the energization of magnets 256, 25! and 252 for the hundreds, tens and units orders, respectively. These magnets are mounted on a frame 253 upon which are also mounted the corresponding magnet armatures each of which is connected respectively to pivoted arms 254, 255, and 256, bifurcated at their upper ends to engage annular grooves in the cor- ;isponding denominational order clutch members The shaft 245 receives one complete rotation at each cycle of a weighing operation and the magnets 256, 25! and 252 are energized one at each cycle under the control of a commutator 251 and also Fig. 12). The emitter 258 rotates in synchronism with the rotation of the shaft 245, making one-half rotation per cycle, while the shaft 245 makes one complete rotation. As the rotor 25.! of the emitter 258 rotates, one of a pair of brushes 266 wipes by a series of contacts 266 which are connected to the sensing contacts I5! to !56, inclusive. The other brush 266 contacts a segment 261 to complete a circuit through the highest value sensing contact closed due to the application of weight, through the emitter 258 and the commutator 251 which determines which one of the indicator magnets 256, 25! or 252 is to be energized.

Briefly the commutator 251 determines that the hundreds magnet 256 will be energized at the first cycle, the tens magnet 25! at the second cycle and the units magnet 252 at the third cycle, all of which will be more fully described later.

Energization of the magnets 256, 25!, and 252 attracts their respective armatures rocking the levers 254, 255 and 256 counterclockwise (Fig. 4) shifting their corresponding clutch members 246 leftwards into mesh with the members 248. It is to be understood that only one of the clutches 248-249 is meshed at a given cycle and that these clutches are rendered effective in timed relation with the rotation of the shaft 245 and the passage of the brush 266 past the differential contacts 266. Thus a differential rotation is imparted to the indicator under the control of the highest value sensing contacts closed.

The rotation of the gears 244 is transmitted directly to the indicator wheels 232, 233, and 234 for the front indicator and this movement is also transmitted to the rear indicators by means of the following described mechanism.

The hundreds order gear 244 meshes with a gear 261 secured to a short shaft 268 mounted in the cross frame 246 and in a bracket 269 secured to the frame 242. A gear 216 secured to the shaft 268 near its opposite end meshes with a gear 21! fast to the hundreds order indicator wheel 235. The tens order gear 244 meshes with a gear 212 which has sleeved thereto a gear 213 which latter gear meshes with a gear 214 secured to the tens order indicator 236. The units order gear 244 meshes with a gear 215 connected by a sleeve 216 to a gear 211 which in turn meshes with a gear 216 secured to the units order indi-g cator 231.

The setting of the indicator wheels is also transmitted to printing wheels and to punch selectors. The hundreds order wheel 235 is secured to the end of a sleeve 219, the tens wheel 238 is secured to a sleeve 288 and the units wheel 231 is secured to a shaft 281 which supports the sleeves 219 and 288 and the rear indicator wheels. The sleeves 219, 288 and the shaft 281 extend toward the right (Fig. and are supported by the frame 248, bracket 289 and a cross frame 282. On the right hand ends (Fig. 5) of the sleeves 219 and 288 and the shaft 281 are secured gears283 each of which meshes with an idler gear 284 on a short shaft 285. These gears mesh with gears 288, one secured to the side of each of three type carriers 281, 288, and 289 rotatably' mounted on a shaft 298. The type carriers 281, 288, and 289 are respectively the hundreds, tens and units wheels, and through the trains just described are adjusted according to the setting of the indicators.

In addition to setting the indicators and the type carriers the differential setting of thegears 244 is transmitted to a plurality of punch selector drums 291, 292 and 293 (Figs. 4, 5, and 11) secured to shafts 294,295, and 298 respectively, mounted in the frame 282 and a frame 291. Gears 298 secured one to each of the shafts 294. 295, and 298 are driven in the following manner: The gears 298 on the shaft 294 meshes with the gear 288 secured to the hundreds order type wheel 281. The gear 298 on the shaft 295 meshes with the tens idler gear 284 and the gear 298 on the shaft 298 meshes with the units order gear 283. Thus the differential setting of the indicators is transmitted to the corresponding denominational order punch selectors.

Arranged wirally around each of the drums 291, 292, and 293 is a series of radially projecting pins 299 (Figs. 4, 5, and 11). The pins 299 in the hundreds order drum 291 are adapted to cooperate with the extended upper ends of punches 388 carried in a frame comprising spaced punch plates 385 and 388 mounted to slide vertically on guide rods 381 and 388. The guide rod 381 depends from a bar 389 projecting inwardly from the frame 241 and the rod 388 is similarly supported by a bracket 318 projecting inwardly from the frame 291. The pins 299 in the tens order drum 292 cooperate with projections 311 extending upwardly from a series of selector fingers 312 pivotally supported on a rod 313. This rod is mounted in the frame 291 and in a bracket 314 on the frame 242. The free ends of the fingers 312 normally rest on the tops of punches 315 mounted in the frame 385-388.

Similarly the pins 299 in the units drum 293 cooperate with projections 318 on fingers 311 pivoted on a rod 318 and having their free ends cooperate with punches 319 in the punch frame 385-388. Springs 328 normally hold the punches in elevated position.

A plate 321 mounted below the punch plate 388 and spaced therefrom forms, together with the plate 388, a channel adapted to receive a record card. After a card is inserted in this channel the punch frame 385-388 together with the plate 321 may be raised, the particular punch 388 having a pin 299 thereabove, and the punches 315 and 319 whose fingers 312 and 311 have pins 299 thereabove being held against movement to effect punching. All of the remaining punches are raised with the frame 385-388, the punches 315 and 319 rocking their fingers 312 and 311 slightly clockwise.

After the type carriers 281, 288, and 289, and the punch selector drums 291, 292, and 293 are set as above described. a printing platen 382 (Fig. 4) is operated to take an impression from the types and the punch frame is raised to effect the punching. In order to operate the printing and punching devices there is provided a manually operable lever 322 pivotally mounted in a bracket secured to the frame 291, and held in its retracted position by a spring 323. The inner end of the lever 322 carries a stud 324 which projects through a slot in one arm of a bell crank 325 pivoted on a stud 328, and which stud 324 projects under a rib 321 secured to the under side of the punch frame.

Obviously when the lever 322 is operated in a clockwise direction the stud 324 will raise the punch frame 385-388 and the plate 321 carrying the card upwardly to effect punching by the selected punches.

The other arm of the bell crank 325 is connected by a link 328 to the lower end of an arm 329 pivotally supported at 338. A spring pressed latch 331 pivotally carried by the arm 329 nor mally restrains an arm 332 also pivoted at 338 against the tension of a spring 333. The arm 332 pivotally supports an arm 334 which carries the platen 382. A spring 335 normally holds the arm 334 in retracted position.

The printing and punching lever 322 is nor mally locked against operation. This locking means includes a hooked projection 338 (Fig. 4) on the bell crank 325 with which projection engages a latch 331 carried by an armature 338 of a magnet 339. This magnet becomes energized late in the third cycle of a weighing operation, (in a manner to be described later) attracting its armature 338 and disengaging the latch 331 from the projection 338. The printing and punching lever 322 may now be operated. After the printing and punching operation is completed and the lever 322 is restored to its normal position by the spring 323, the latch 331 is reengaged with the projection 338 by a spring 348.

Operation of the lever 322 rocks the bell crank 325 counterclockwise and through the link 328 rocks the arm 329 in the same direction. At this movement the latch 331 draws the arm 332 therewith to lower the platen arm 334. The beveled right hand end of the latch 331 wipes by a stud 341 rocking the latch to release the arm 332 to the action of the spring 333 which rocks the arm 332 sharply clockwise to throw the platen sharply against the types taking an impression therefrom upon a suitable record material. The movement of the arm 332 is limited by a stop stud 342 so that when the lever 322 is restored by the spring 323 thus restoring the bell crank 325 and the arm 329, the latch 331 resumes its position to the left (Fig. 4) of the arm 332 in readiness of the next succeeding printing and punching operation.

The indicator drive shaft 245 (Fig. 4) is driven by a motor 342 through a train of gears as follows: gear 343 on the motor shaft, an intermediate gear 344 on the frame 248, a gear 345 loosely mounted on a reset shaft 348 (see also Figs. 6 and 10) and a gear 341 loosely mounted on the shaft 245. The gear 341 drives the shaft 245 through the medium of a clutch including a notched hub 348 on the gear 341 and an arm 349 secured to the shaft 245, said arm 349 carrying a coupling 358 which is normally held out of cooperative relation with the notched hub against the tension of a spring 351 by a shouldered armature 352 controlled by magnets 353.

As will be described later the magnets 353 are energized under the control of the sensing lever 80 and its cooperating contact control lever I40, and, when energized, attract the armature 352 freeing the coupling 350 to its spring 351 and also freeing the arm 349 and shaft 245 for rotation. When the notch in the hub 348 arrives opposite the projection on the coupling 350 the spring 351' engages the coupling with the notch so that the shaft 245 is rotated therethrough.

. Indicator aliners Suitable aliners are provided to aline the indicators when they are at rest and means is provided to disengage the aliners when the indicators are being set and when they are being reset to zero. The aliners include a bar 354 (Figs. 4, 5, and 7) pivoted in the bracket 239 and in the frame 240, the bar 354 having a plurality of fingers 355 thereon cooperating with pins 356 projecting from the sides of the gears 243 opposite the sides to which the indicators are secured. Fast on the right hand end of the bar 354 (Figs. 4, 5, and 7) is an arm 351 connected by a link 358 to an arm 359 pivoted on a stud 360 in the frame 240 and hubbed to a cam arm I having a broad flange at its free end normally held by a spring 363 in contact with the low portion of a cam 364 integral with a gear 365 on the shaft 346, and in contact with a recess in the periphcry of a cam 366 fast on the shaft 346. An arm 368, upon which is mounted a coupling 369 adapted to cooperate with a notched hub 310 on the gear 345, is likewise secured on the shaft 346 adjacent the gear 345 (see Fig. 6).

The gear 365 meshes with a gear 316 fast on the shaft 245 to operate the aliner cam 364 on weighing operations when the indicators are being set, and the coupling 369 is operated by an armature 311 under the control of reset clutch magnets 318 to couple the aliner cam 366 to the gear 345 on reset operations.

Obviously when the coupling 350 (Fig. 6) is rendered effective to couple the gear 341 to the shaft 245, this shaft will be rotated until such coupling is broken which occurs at the end of the third cycle of a weighing operation. The gear 316 drives the gear 365, the latter rotating in a counterclockwise direction. As soon as the gear 365 starts to rotate the cam 364 rocks the lever 36I and arm 359 clockwise which, through the link 358 rocks the arm 351 and the aliner bar 354 counterclockwise to move the-fingers 355 out of the path of the pins 356 to permit free rotation of the indicator wheels 232, 233, and 234. Shortly after the wheels have rotated ten increments or steps the low portion of the cam 364 comes opposite the flange 362 of the arm 36! permitting the spring 363 to restore the aliner mechanism to its effective position. The cam 366 rocks the lever 361 to operate the aliner mechanism on reset operations.

Reset mechanism After the completion of a weighing operation, and after the printing and punching operation has been manually effected the operator removes the load from the platform 23 and since the offset weights are still applied to the lever 4| (Fig. 3a) this lever becomes unbalanced which. as will be later described, initiates a reset operation by effecting the energization of the reset clutch magnets 318.

When these magnets are energized they rock the armature 311 (Fig. 6) releasing the coupling 369 to the influence of its spring. This couples the gear 345 to the shaft 346. Secured to this shaft is a gear 319 which meshes with a gear 380 mounted on a short shaft 381 and hubbed to a companion gear 382 (see Fig. 8). The gear 382 meshes with a gear 383 on the indicator shaft 238. The gear 345, driving through the tra n just described imparts one rotation in a counterclockwise direction as viewed in Fig. 8, to the gear 383 and the indicator shaft 238 to reset the front indicator wheels. the rear indicator wheels, the type wheels and the punch selector drums to zero or normal positions.

The gear 383 is countersunk to receive a disc 384 which is secured to the end of the indicator shaft 238 by a screw 385. The gear 383 and the disc 384 are yieldingly coupled together by a sprng 386 but are normally rotated in unison through the medium of a pin 381 mounted in the disc 384 and projecting into a slot (not shown) in the gear 383. Near the end of the rotation of the gear 382 a tappet 388 secured to the side of the gear 382. strikes a block 389 secured to the disc 384 imparting a slight overthrow to the shaft 238 compressing the spring 386 which, as soon as the tappet 388 clears the block 389, restores the shaft 238 and the block 289 to the positions in wh ch they appear in Figure 8. This action insures the restoration of the parts to their normal home position.

The rotation of shaft 238 resets the indicator wheels to zero in a manner well known in the art and which is fully disclosed in the patent to C. D. Lake, No. 1,600,414 issued September 21. 1926 to which reference may be had for a complete understanding of the resetting device.

As set forth above the cam 366 (Fig. 7) operates on resetting operations to actuate the aliner bar 354 to first remove the aliner fingers 355 from the path'of the pins 356 and to then. at the end of the operation. reengage the fingers 355 with the pins to retain the indicators, type wheels and punch selector drums in zero posi tion until the next weighing operation.

Operation-first cycle The motor starts operating immediately driving the train of gears it be assumed that p aced on the platform 23 (Fig. 3a). The lever system below the platform may be of'any convenient ratio, for instance, 20 to 1. One twentieth of the load. as 43.2 weight units will be applied to the link 24 (Fig. 3a) and to the point 39. One-half of the load applied to 39, that is 343, 344, 345, and 341. Let

a load of 864 weight units is P 21.6 weight units is applied to the point 56, and

as stated above, the ratio of the levers 51 and 6| is 100 to 1, therefore one one-hundredth of 21.6 weight units, or .216 weight units is applied to the link 14 and to the point 15 (Fig. 3). This load of .216 is distributed in equal loads to the ten sensing levers, each of said levers 80 to 89 inclusive receiving .0216 weight units. The adjustment of counter balances 98 to 99 is such that this load, being applied to each of the sensing levers, is sufficient to close all of the contacts I50 for the 0 lever 80, up to and including the contacts I58 for the 8 sensing lever, but is not enough to close the contacts I59 for the 9 sensing lever.

The closure of the contact I50 establishes a circuit from the line 392 (Fig. 12) contacts I50, a relay coil 394 to the line 393. This energizes the coil 394 which closes contacts 395. The closure of contacts 395 is delayed by the use of a dash pot 396. When the contacts 395 are closed a circuit is established from the line 392, contacts 395 through the clutch magnets 353 to the line 393, energizing the magnets 353 to release the coupling 350 (Fig. 6).

The magnets 353 when energized also close contacts 391 setting up a holding circuit from line 392, cam contacts 398 (closed early in the first cycle), contacts 391, magnets 353 to line 393. This circuit maintains the magnets 353 energized throughout the three cycles comprising a weighing operation. Near the end of the third cycle the contacts 398 open deenergizing the magnets 353. The gear 341 now' picks up the shaft 245, which, through a train of gears 399, 400, and 40I (Fig. 4) rotates the impulse emitter brushes 260 (Fig. 12) in synchronism with the rotation of the clutch members 249.

When the brush 260 comes into contact with the contact 266 connected to the highest value contacts II to I59 which are closed, the "8 contact I58 in this example, a circuit is set up from the line 392, the 8 contacts I58, wire 402, contact 266, brushes 260, contacts 405, 404, and 403. a brush 406, contact 401, under brush 406 during the hundreds weighing cycle, a brush 408, wire 409, through the coils of the hundreds indicator clutch magnet 250, wire 4I0 to line 393. As stated above energization of the magnet 250 couples the hundreds indicator gear 244 (Figs. 4 and 5) to the shaft 245 to thus set the indicator wheel according to the time of energization of the magnet 250.

Energization of the magnet 250 closes contacts 4II setting up a holding circuit from the line 392, cam contacts 2, contacts I now closed, magnet 250, wire 4I0 to line 393. At the same time the magnet 250 opens the contacts 403. The magnet 250 therefore is maintained energized from the 8 position to the 0 position thus holding the hundreds clutch 248-249 engaged so that the hundreds indicator wheel is rotated eight spaces. The contacts 4I2 open just after the 0 position breaking the holding circuit and deenergizing the magnet Simultaneously with the completion of the circuit through the hundreds indicator clutch magnet 250 a circuit also extends from the emitter 258 by a wire H3 and a brush 4 to a common contact strip M5 on an offset weight selecting commutator 4I6, mounted on the indicator drive shaft 245 (Figs. 4 and 5) and adapted to make one revolution therewith per weighing cycle of the machine. At the time the brush 260 of the impulse emitter 258 makes contact with the "8 contact 258, the 8" combination of segments 1 will be under a series of brushes H8 and concurrent circuits will be extended through three segments 1 comprising the 8 group to corresponding brushes 9 now in contact with a series of bridging segments 420 on the commutator 251 mounted on a shaft 422 and adapted to be driven through a train of gears 423, 424, 425, and 426, the latter gear being fast on the indicator drive shaft 245 (see Figs. 4 and 5). The ratio of this train of gears 18 such that the commutator 251 makes one third of one rotation for each weighing cycle bringing the segments 420 under the brushes H9 at the first or hundreds cycle, segments 421 are under the brushes 428 at the second or tens cycle and segments 429 are brought under brushes 430 at the third or units weighing cycle.

From the brushes 4I9 for'the first segment 420 on the left (Fig. 12) the circuit extends through a wire 436 to the offset weight magnet I85 (see also Fig. 3a). From the next segment to the right the circuit extends to the second segment 420 from the left and thence by a wire 431 to the offset weight magnet I84. From the right hand segment 1 of the 8" group the circuit extends through the corresponding brushes H9 and segment 420, wire 438 to the magnet I83. Since there is no segment H1 in the right hand column no energy will be transmitted to the right hand segment 420 which is connected to the magnet I82 by a wire 439, consequently this magnet remains unenergized and its weight I (Fig. 3a) is not applied to the lever H. The magnets I83, I84, and I85 being energized apply their weights I1I, I12,'and I19 respectively to the lever H to balance the hundreds of weight units representing that part of the load which is sensed at the first cycle.

Energization of the offset weight magnets closes contacts 440 energizing corresponding companion magnets I from line 392, cam contacts 442, magnets 4, contacts 440, wire 443 to line 393. The magnets I hold the armatures I86 for the selected weights I1I, I12, and I13 in operated position after their associated magnets I85, I84, and I83 are deenerglzed due to the opening of the contacts 403. The contacts 442 are normally closed and open only on a reset cycle thus maintaining the selected magnets 44I energized and the offset weights controlled thereby applied to the lever 4I until a reset cycle occurs.

The offsetting weight for the hundreds amount has now been determined and applied to the lever 4I. Near the end of the first weighing cycle the ratio of the lever system 40, 51, and 6I is changed from 1 to 200, to 1 to 20. This is effected automatically in the following described manner: The commutator 251 is provided with three segments 444, 445 and 446 which are energized from the line 392, brush 441 and common ring 448. Near the end of the first cycle the segment 444 passes under a brush 449 extending a circuit from the line 392, brush 441, ring 448, segment 444, 449, the previously described magnet 205 (see also Fig. 30) wire 443 to the line 393. This energizes the magnet 205 which attracts its armature 206 and operates the lever 208 to raise the link 59 out of contact with the point 60 in the lever 6| and to apply the balance 2 to' the point 2I2. As described above, this changes the ratio of the levers 40, 51, and H from 1 to 200 to 1 to 20.

Energization of the magnet 205 closes contacts 450 setting up a holding circuit from line 392 through cam contacts 45I, contacts 450, magnet 205, wire 443 to line 393. The contacts 45I are normally closed and are opened only on reset cycles, consequently the magnet 205 remains energized until such reset cycle occurs.

Operation-second cycle The machine now proceeds uninterruptedly brush into the second cycle at the beginning of which 78 cycle the machine is in the following condition: Weights have been applied to ofl'set the 800 weight units, and the ratio of the levers 40, 51, and H now is 1 to 20. The scale is in an unbalanced condition to the value of the remaining 64 weight units.

The commutator 251 has rotated from the point at which it is illustrated diagrammatically in Figure 12 to a point where the brushes 406 and 408 are between the segment 401 and a segment 43I. The brushes 9 are between the segments 420 and 421 and the brushes 449 are between the segment 444 and the segments 445 and 446. The commutator H6 is in its home position, that is, with the brushes 4I8 just ahead of the 9 group oi segments 4I1.

Early in the second cycle the brush 260 wipes by the contacts 266 for the 9, 8, and '7 orders but since the unbalanced weight is now but 64 weight units only the sensing contacts I50 to I56 inclusive are closed consequently the circuits are not completed until the brush 260 wipes the 6 contact 266. At this time a circuit is set up through contacts I56, wire 402 the 6" point of the emitter 258, contacts 405, 404, and 403, brushes 406 and 408 and the segment 43I now thereunder, wire 452, the tens indicator magnet 25I, wire 0 to line 393. The magnet 25I closes its contacts 453 setting up a holding circuit from line 392, contacts 4 I2, contacts 453, magnet 25I wire 0 to line 393. The magnet 25I opens the contacts 404 and also engages the tens indicatorclutch 248-249 thus causing the tens indicator to be rotated six spaces to indicate 6.

Concurrently with the circuit through the magnet 25I a circuit is completed throughthe wire 3, brush 4I4, segments 4" in the 6 position on the commutator 4I6, brushes 8 for the first and second columns of segments 4", segments 421, brushes 428, wires 454 to the tens ofiset weight magnets I95 and I94, wire 443 to line 393.

Energization oi the magnets I94 and I95 (see Fig. 3a) apply the weights I16 and I11 to the lever M to balance the 60 units of weight. The magnets I94 and I95 also close contacts 440 completing a holding circuit through their companion magnets through the contacts 442, which latter circuit holds the magnets 44I energized to maintain the proper selected weights applied until the contacts 442 are opened on the next succeeding reset cycle.

Near the end of the second cycle the segments 445 and 446 come under the brushes 449 simultaneously energizing magnets 2I6 and 12 which magnets close contacts 455 and 456 respectively completing holding circuits through contacts "I contacts 455 and 456, magnets 2I6 and 12, wire 443 to line 393.

As previously set forth these magnets 2 I6 and 12 (see also Fig. 3a) operate the links 65 and 68 to change the lever ratio from 1 to 20, to 1 to 2 preparatory to sensing out the units of weight at the third cycle.

' Operation-third cycle At the beginning of the third cycle the commutator 251 is in position with the brushes 406 and 408 between the segment 43I and a segment 451, the brushes 9 are between the segments 421 and 429. The segments 445 and 446 have passed the brushes 449 and the segment 444 will not come under the brushes 449 until late in the first cycle oi the next succeeding weighing operation. The commutator H6 is in its normal position as shown in Figure 12. The indicators now stand at hundreds order "a", tens order "6 and units order at 0. The 800 weight units and the 60 weight units have been balanced by the application of the proper oiIset weights and the scale is unbalanced by the remaining 4 weight units.

The portion of this load applied to the sensing levers is just suflicient to close the sensing contacts up to and including the 4" contacts I54. As the brush 260 wipes the contacts 266 the previously described circuits are not made until the brush passes the 4 contact. When this occurs a circuit is completed through contacts I54, wire 402, emitter 258, contacts 405, 404, and 403, brushes 406-408 and the segment 451 now under these brushes, wire 458, the units indicator clutch magnet 252, wire M0 to line 393. Energization of magnet 252 in addition to operating the units clutch so that 4 may be run onto the units indicator wheel, closes contacts 459 completing a holding circuit from line 392,-oontacts 2, contacts 459, magnet 252, wire 4I0 to line 393. The magnet 252 also opens contacts 405.

When the brush 260 touches the 4 contact 266 a circuit is also completed through wire 4I3, brush 4, ring M5, the segment 4" in the 4 position on commutator 4I6, brush 8, the appropriate brushes 9 and the units segments 42, wire 454 to the magnet 204, wire 443 to the line 393. The magnet 204 closes the appropriate contacts 440 energizing the corresponding magnet I. The magnet. 204 applies the weight I M (Fig. 3a) to the lever M at the point 46 to balance the 4 units of weight. The indicators and type carriers now stand at "864 and the punch selectors 29I, 292, and 293, (Fig. 5) have been correspondingly set.

Late in the third cycle the cam contacts 398,

open, and since at this time there is no effective weight applied to the sensing levers, the contacts I50 associated with the "0 lever 30 open deenergizing the clutch magnet 353 and bringing the indicator drive shaft 246 to a stop.

Also near the end of the third weighing cycle latch 331 to permit operation of the printing and punching lever 322.

The scale is now in a condition of balance with the load on the platform and the indicators and type wheels set to display and print characters indicating the weight of the load on the platform.

The load may now be removed which unbalances the scale and automatically initiates a'reset operation. Associated with thelever 4I (Fig. 3a) is a finger lever 480 mounted on a fixed pivot and carrying at its opposite end a pair of laterally projecting pins 461 embracing the center blade oi a two-way switch. The outside members of this switch are connected together and to the line 392 and the center blade is connected through a magnet 468 to the line 393. This switch carries upperand lower contacts 469. Upon removal 01' the load from the platform the scale becomes unbalanced under the influence of the applied ofl'set weights rocking the lever 4I very slightly counterclockwise. The finger lever 480 following the lever 4I closes the upper contacts 469 thus completing a circuit from line 392, contacts 469, magnet 466 to line 393. Energization of magnet 468 closes contacts 410 completing a circuit from line 392, contacts 410, contacts 41i closed upon energization of magnet 462, reset clutch magnet 318 to line 393.

The magnet 318, when energized, releases the coupling 369 which effectively couples the reset shaft to the continuously rotating gear 345 to effect a reset operation.

The balance lever 4I also exercises control over a signal device 412 to indicate the condition of the scale, that is, whether the scale is in balance or out of balance. The magnet 468 when energized opens contacts 413 which contacts are normally closed and form part of a circuit from line 392, contacts 414, contacts 413, signal magnets 415 to line 393. So long as the scale is in balance the magnet 468 remains deenergized allowing the contacts 413 to remain closed to maintain the cir-' cuit through the signal magnets 415. These magnets being energized rock their armature 416 (Fig. 9) clockwise. The upper end of the armature 416 is bifurcated and embraces a pin 411 projecting from the pivoted arm supporting the signal. 412. When the armature 416 is rocked clockwise, the signal 412 due to the coupling 411, rocks counterclockwise to display a suitable signal indicating that the scale is in balance.

When the contacts 466 (Fig. 12) close in either direction the magnet 468 becomes energized opening the contacts 413 to deenergize the magnet 415, whereupon a spring 416 rocks the armature 416 counterclockwise, rocking the signal 412 clockwise to the positions in which the parts appear in Figure 9 wherein a suitable warning signal is displayed indicating that the scale is out of balance. It may be stated here that the contacts 414 open at the beginning of the first cycle of a weighing operation and close near the end of the third cycle, thus controlling the signal to indicate that the scale is out of balance durin weighing operations. The contacts 413 control the signal during reset cycles and while the machine is at rest to indicate the condition of the scale.

During the reset cycle the indicator wheels, type wheels and punch selectors are restored to their zero positions in a manner previously described. Also during the reset cycle the contacts 464 (Fig. 12) open to deenergize the magnet 462, contacts 45I open to deenergize the ratio control magnets 12, 2I6, and 205. Also the contacts 442 open to deenergize the offset weight magnets I which were energized during the preceding weighing operation.

It sometimes happens that after the offset weights have been applied for the hundreds, tens and units orders'there still remains on the platform an unoilset weight, just under the minimum capacity of the scale to sense, but sufficient to maintain the 0 sensing contacts I56 closed.

In order to bring the machine to a stop at the end of the third weighing cycle under this condition the magnet 462 when energized late in the third weighing cycle, opens contacts 419 in circuit with the magnet 394 and the 0" sensing contacts I50, thus deenergizing the magnet 994 which allows contacts 395 to open. The clutch magnets 353 are then deenergized under the control of the cam contacts 396 in the above described manner.

The magnet 462 remains energized under the control of cam contacts 464 which remain closed during the interim between the weighing operation and the reset cycle. The contacts 464 open during the reset cycle deenergizing magnet 462, allowing contacts 419 to close.

The load having been removed from the platform in .order to initiate a reset cycle the scale is now in complete balance and the 0 sensing contacts I50 are open.

At the end of the reset cycle the scale is in balance with no offset weights applied and no load on the platform. The recording and indicating mechanisms are standing at zero and the scale is in readiness for another weighing operation. It may be stated that, if after the weighing operation is completed and either before or after the printing operation, the operator, instead of removing the load from the platform, adds additional load thereto, the scale becomes unbalanced closing the contacts 469 and automatically initiates a resetting operation. At the end of this resetting operation the scale is still in an un anced condition and the contacts I50 for the 0 sensing lever are closed which automatically initiates another weighing cycle continuously with the resetting cycle, during which the total load now on the platform is weighed out. The same operations are induced should a part of the load be removed from the platform after the weighing operation and before the resetting operation.

Also if the operator should increase or diminish the load on the platform during a weighing operation the scale will be unbalanced at the end of said operation and a resetting operation will be automatically effected continuously with the weighing operation and another weighing operation automatically initiated at the end of and continuously with the resetting cycle.

M odiflcation Figures 14 and 15 illustrate a modified form of the invention employing three sets of denominational order sensing lever systems instead of the above described ratio changing lever system and one set of sensing levers. These three sets of sensing levers are hereinafter referred to as the hundreds order, tens order and units order sensing levers. The units order sensing levers are exactly like the previously described sensing levers and those for the tens and hundreds orders are the. same as the units order levers except that the 0 levers have been omitted and the left hand ends of the corresponding levers II2 (Fig. 14) are mounted on fixed pivots. The same parts in each of these lever systems are given the same reference characters and in the following description will be further distinguished by reference to the denominational order to which they belong.

In this modified embodiment of the invention the load applied to the links 24 and 36 (Fig. 14) is applied to a point 500 to a lever 50I having its left hand end pivotally connected at 502 to a link 563 depending from the lever 16 of the units order sensing lever system. The right hand end of the lever 50I is pivotally connected at 504 to a link 505 whose upper end is pivotally supported at 566 to a lever 501. ends of the lever 501 are respectively connected at 506 and 509 to links 5I0 and 5H having their upper ends pivotally supported by the levers 16 for the tens and hundreds order respectively.

Obviously a load applied to the point 500 is distributed unequally to the links 506 and 505, the link 503 receiving the greater portion of the load. The smaller portion of this load applied The left and right hand to the lever 505 and to the point 506 of the lever 501, where this portion of the load is unequally divided between the points 508 and 509, the greater portion being applied through the link 5I0 to the lever 16 for the tens order and the lesser portion is applied through the link 5 to the hundreds order lever 16.

This modified form of the invention is organized to make three cycles at each weighing operation similar to the cycles already described with the difference that instead of changing the ratios of certain levers the weight applied is sensed at the first cycle by the hundreds sensing levers 8| to 89, inclusive, at the second cycle by the tens sensing levers and at the third cycle by the units sensing levers.

Assuming that a load of 864 weight units is placed on the platform 23 and is applied through the lever system under this platform and through the le'vers 50I and 501 to all of the sensing levers. The greater part of the load applied to the lever 50I going to the .units sensing levers closes all of the units contacts I50 to I59, inclusive, and the greater part of the load applied to the lever 501 going to the tens sensing levers closes all of the tens contacts I5I to I59, inclusive. The load applied through the link 5 to the hundreds sensing levers is just sufllcient to close the hundreds contacts I5I to I58, inclusive, but not the 9 contact I 59.

The hundreds order is sensed at the first cycle and reads out the 800 units of weight in a manner to be later described, and an offset weight is applied to balance of! this portion of the load. The scale is still unbalanced by 64 units of weight which is applied in exactly the same manner to all of the sensing levers. This load is sufiicient to close all of the units sensing contacts and the tens sensing contacts up to and including the "6 contact I56. That portion of the load applied through the link 5 is insuflicient to close any of the hundreds contacts I 5I to I59 inclusive.

The tens order is sensed at the second cycle and ofiset weights applied to oifset'the 60 units of weight leaving the scale still unbalanced by the 4 units of weight. This remaining load closes the units contacts I50 to I54, inclusive, but those portions of'it applied to the tens and hundreds order sensing levers 8I to 89, inclusive are insufficient to close any of the contacts I5l to I59 for these orders. r

The units order is sensed at the third cycle and offset weights automatically applied to balance oil the 4 units of weight bringing the scale into balance and stopping the machine in the manner previously described.

Each of the levers 16 is provided with adjustable stops 5I2 to limltthe downward movement thereof when a load is applied to the platform. The. stops 5| 2 are adjusted to permit just willcient movement of their respective levers 16 to permit closing of all of the sensing contacts.

Referring now to Fig. 15 it may be noted that certain elements of the circuit diagram of the modified embodiment of the invention are exactly like the analogous elements in the circuit diagram shown inFigure 12. These identical elements include the controls at the left hand part of Figures 12 and 15, the weight selecting commutator 6 (Fig. 12) the commutator 251 with the exception of the ratio lever change control segments 444, 445, and 446 which are dispensed with in the modification (Fig. 15).

A description will now be given of an operation of the modified scale with reference to Figure 15.

The sensing contacts for the hundreds, tens and units orders are connected by a wire 5| 3 to the line 392. The hundreds order sensing contacts are severally connected by wires 524 to corresponding segments 525 on an impulse emitter 53I. The tens sensing contacts are similarly connected by wires 532 to corresponding segments 533 in the emitter 53I and the units sensing contacts are connected by wires 534 to segments 535 in the emitter 53I. The rotor 536 of the emitter 53I carries two brushes 531 and 538 the former being adapted to wipe by the denominational segments 525, 533, and 535 at the three cycles comprising a weighing operation while the brush 538 contacts a common ring 539 connected serially through the contacts 405, 404, and 403 to the brushes 406, 408 and by the wire M3 to brush M4. The commutator 251 rotating onethird of one revolution per. cycle brings the segments 401, 43I, and 451 successively under the denominational brushes 406 and 408 to complete the circuits to the indicator clutch magnets 250, '25I and 252. The brush 4 energizes the conductor M5 and the segments 4", those brushes 8 which are in contact with segments 1 transmitting the current to brushes 9, 428, and 430 which are bridged at successive cycles by the segments 420, 421, and 429 for the purpose of energizing the selected offset weight magnets.

When a load is applied to the platform, for ex ample, a load of 864 weight units, all of the units and tens sensing contacts and the hundreds contacts up to and including the 8 contact close. Closure of the contact in the units order, as previously set forth, energizes magnet 394 which closes contacts 395 under the control of the dash pot 396 to energize the clutch magnets 353. As soon as the clutch controlled by these magnets becomes effective the shaft 245 (Figs. 4 and starts rotating driving the commutator 251, the commutator M6 and the rotor 536 for the emitter 53I. The segment 401 comes into contact with the brushes 406, 408 early in the cycle directing the current to the hundreds order sensing contacts so that when the brush 531 wipes the 8 contact 525 on the emitter 53I, a circuit is established from the line 392, wire 5I3, 8 contacts I58 for the hundreds order, wire 524, 8" contact 525, brush 531, brush 538, ring 539, contacts 405, 404, and 403, brush 406, hundreds segment 401,

magnet 250, wire 0 to line 393.

Another circuit extends concurrently over wire 4I3, brush 4, conductor 5, to the 8" combination of segments 4I1 now in contact with brushes 4| 8 to the brushes 4I9 which are bridged by the hundreds segments 420 at this cycle, wires 436, 431 and 438 to the hundreds offset weight magnets I83, I84, and I 85 energizing those magnets to apply the weights Ill, I12, and I13 (Fig.

3a) in order to balance off the 800 units of weight. Energization of the magnets I83, I84, and I85 closes corresponding contacts 440 to energize holding magnets I. This is necessary because as soon as the magnet 250 is energized it opens contacts 403 to interrupt these circuits and closes contacts 4 to set up a holding circuit through the cam contacts 2.

The hundreds indicator clutch magnet causes the engagement of th hundreds clutch whereby 8 is run onto the hundreds indicator wheel.

At the second cycle the brush 53-1 wipes the tens contacts 533 on the emitter 53I. Since the hundreds order weight units were balanced oil at the first cycle the scale is unbalanced by the remaining 64 units of weight at the beginning of the second cycle. This closes all of the units sensing contacts and the tens contacts up to and including the "6 contact so that, when the brush 53'! wipes the 6 contact I50, a circuit is set up from line 392, wire 5l3, tact 156, 6 contact 533, brushes 331 and 338, ring 330, contacts 405, 404, and 403, tens brushes 406 and 408 and the tens segment 43L wire 452, tens clutch magnet 25!, wire M0 to line 393. Concurrently a circuit is completed through the 6 combination of segments M! on the commutator M6, and through the tens segments 421 to the proper ones of the offset weight magnets I92, I93, 194, and 195, which in this case includes the weights I94 and I95 to balance the 60 weight units.

At the beginning of the third cycle the scale is unbalanced by the 4 weight units. is load is not sufficient to close any of the tens or hundreds sensing contacts and is just sufficient to close the units sensing contacts up to and including the 4 contacts I54, consequently the circuits are completed when the brush 531 wipes by the 4 contact 535 of the units group on the emitter 535. This energizes the units indicator clutch magnet 25?. and selects the 4 group or combination of segments 4i! which in this particular instance comprises a single segment 4H. The weight selecting circuit is directed to the units weight magnet 204 (Figs. 15 and 3a) apply ing the weight m to balance off the 4 weight units.

Near the end of the third cycle the segment 480 bridges the brushes 4?}! energizing magnet 462 which opens contacts 419 ole-energizing magnet 394 which in turn opens contacts 3.5 to deenergize the clutch magnets thus bringing the machine to a stop at the end of the cycle.

A reset cycle is initiated and the machine is controlled during a reset cycle exactly as set forth above, also the printing and punching mechanisms are controlled and operated as described above.

While there has been shown and described and pointed out the fundamental novel features of the invention as applied to a single modification, it will be understood that various omissions and substitutions and changes in the form and details of the device illustrated and in its operat on may be made by those skilled in the art without departing from the spirit of the invention. It is the intention therefore to be limited only as indicated by the scom of the following claims.

What is claimed is:

1. In a weighing scale, the combination with a load support, of a series of load sensing devices having different combinations of positions, each such combination representing a diiferent load value, a pivoted beam operatively connected to the load support, a plurality of load offsetting devices, and means controlled by the sensing devices according to their combinational position to selectively apply the ofisetting devices to the beam to offset load on the support.

2. In a weighing scale, the combination with a load support, of a series of load sensing devices, means intermediate the support and the sensing devices to distribute the load to the sensing devices, a pivoted beam, a plurality of load ofisetting devices, and means controlled by the sensing devices to selectively apply the load ofisetting devices to the beam.

3. In a weighing scale, the combination with a load support, of a series of load sensing devices,

tens order sensing con- 1 means interconnecting the support and the sensing devices to distribute the load to said sensing devices, a. plurality of indicators, and means controlled by the sensing devices to set the indicators.

lng devices upon application of a load to the load support to couple the shaft to the operating mechanism, means controlled by the sensing devices to determine the extent of operation of the indicators, a reset shaft for the indicators, and means to couple said reset shaft to the operating mechanism to reset the indicators to zero.

6. In a weighing scale, the combination with a load support, and cyclically operating mechanism with means to drive it through a plurality of cycles at each weighing operation, of a series of load sensing devices, a plurality of indicators, a drive shaft actuated by the operating mechanism through one rotation at each cycle,. and means controlled by the sensing devices to couple the indicators to the shaft in successive cycles, a different indicator each cycle, for differential operation during the cycle by the shaft.

7. In a weighing scale, the combination with a load support, of a series of load sensing devices, a plurality of denominational order recording elements, means coacting with the sensing devices to determine the value of the load sensed by the sensing devices, and means controlled by the first-mentioned means to successively set the denominational order recording elements according to the value of the load.

8. In a weighing scale, the combination with a load support, of a plurality of sets of load sensing devices each of said sets having a denominational significance, a plurality of denominational sets of load ofisetting devices, means connected to the load support and to which the load offsetting devices are applied to counterbalance the load, and instrumentalities controlled by the sensing devices to selectively apply to said means the oil'- setting devices from the corresponding denominational set of such devices.

9. In combination; load weighing mechanism, a series of sensing elements simultaneously and selectively reactive to operation of the weighing mechanism upon application of a load to the latter to sense digital values of a denominational order of the applied load, and automatic load manifesting means controlled by the sensing elements after they have completed the sensing of said order of the load for operation according to the digital value of the load sensed by the elements.

10. In combination; load weighing mechanism, sensing elements in ordinal relationship selectively responsive to operation of the weighing mechanism for sensing a denominational order of load values acting on said mechanism, each such element being selectively responsive to a. dlfierent digital value of the load order, control devices corresponding to said elements, one device to each I element to sense the response of the element to the load, and value manifesting means selectively controlled by said devices to manifest the load value to which said elements respond.

11. In combination; load weighing mechanism, levers selectively cooperating with the weighing mechanism to sense a denominational order of load values acting on said mechanism, each such lever selectively sensing only a single, diiferent digital value of the load order, and selectively operable automatic load manifesting mechanism controlled for operation by said levers in accordance with the load value sensed thereby.

12. In combination; load weighing mechanism including load counterbalance mechanism, an ordinal series of movable sensing elements cooperating with the weighing mechanism to sense an order of load values, each such element having selective cooperation with the weighing mechanism to sense a different digital value of the load order, and means controlled by said elements in accordance with the load value sensed thereby for selectively operating said load counterbalance mechanism to counterbalance the load acting on said weighing mechanism.

13. In combination; load weighing mechanism including factor levers to factor the load into separate load force portions, load value sensing elements connected to the factor levers each to receive and respond to a separate load force portion to sense load values, selectively operable load manifesting mechanism, and electrical controlling means cooperatively connecting said elements and said selectively operable mechanism to control operation of the latter according to the load values sensed by said elements.

14. In combination; load weighing mechanism, an order of electrical sensing elements responsive to operation of the weighing mechanism under a corresponding order of load values, each such element corresponding to and sensing a different digital value of the load order, value manifesting means, and electrical circuits selectively controlled by said elements for governing operation of the value manifesting means to manifest the load valuesensed by said elements.

15. In combination; load weighing mechanism including factor levers to factor the load into separate load force portions, load value sensing elements connected to said factor levers to each receive and respond to a single one of said load force portions, circuits selectively controlled by said elements in accordance with the load value sensed by the latter, and selectively operable load manifesting mechanism selectively controlled for operation by the circuits in accordance with the operation of the sensing elements.

16. In combination; load weighing mechanism. a series of circuits corresponding to different load values, means automatically responsive to operation of the weighing mechanism upon application 01' a load thereto for selecting one of said circuits for effective operation, load manifesting mechanism to be controlled by said selected circuit when the latter is rendered effective, and an automatic actuator including a cyclically operable contactor having an invariable cycle of operation for rendering the selected circuit eflective during said cycle to control the last-named mechanism according to the load value corresponding to said circuit.

17. In combination; weighing mechanism, a series of circuits corresponding to different load values, means automatically responsive to appll cation of a load to the weighing mechanism for having an invariable cycle of operation, commutator contacts one in each said circuit successively engaged by said contactor during its cycle 5 to complete the partially closed circuit, and load manifesting mechanism selectively controlled by the completed circuit.

18. In combination; load weighing mechanism, a series of circuits corresponding to a denominational order of load values, means controlled by the weighing mechanism for partially completing one of said circuits, a commutator having a set of contacts, one in each circuit, a feeler, automatic power means having an invariable cycle of operation for moving said feeler and contacts relatively to cause the contacts to be successively engaged by said feeler to thereby close the partially completed circuit during said cycle, and an indicator for manifesting said order of load values and controlled by the completed circuit to manifest the load value corresponding to the latter circuit.

19. In combination; load weighing mechanism, settable offsetting weights to be applied to said mechanism to counterbalance the load, circuits for selectively controlling application of said weights to said weighing mechanism, means controlled by the weighing mechanism to selectively and partially complete said circuits, and a commutator having actuating means separate from the weighing mechanism for completing the selected circuits to cause application of the oil'- setting weights to counterbalance the load.

20. In combination; load weighing mechanism, settable oifsetting weights to be applied to said mechanism to counterbalance the load, electrical sensing instrumentalities cooperating with the weighing mechanism to sense the load value, a timed contactor cooperating with the load sensing instrumentalities to read out a. timed impulse equivalent to the load value sensed by said instrumentalities, means timed synchronously with the contactor for receiving the timed impulse from the latter, and circuits controlled by the latter means to apply the weights to said mechanism to counterbalance the load value sensed by said instrumentalities.

21. In combination; load weighing mechanism, settable offsetting weights to be applied to said mechanism to counterbalance the load, electrical sensing instrumentalities controlled by the weighing mechanism to sense the load value, a timed electrical device cooperating with the instrumentalities to read out a timed impulse equivalent to the load value sensed by said instrumentalities, means synchronously operated with the timed device for receiving the impulse therefrom, and a combination of circuits closed by said means upon receiving said impulse to apply a combination of said oil'setting weights to said mechanism to offset the load value sensed by said instrumentalities.

22. In combination; load weighing mechanism, electrical sensing means controlled by said weighing mechanism to sense load values, an impulse emitter cooperating with said electrical sensing means to emit electrical impulse equivalents of the load, separate load manifesting devices, separate electrical controls for said devices, and means for distributing each of said emitted impulses simultaneously to said separate electrical controls to cause related operation of the both devices according to the load values sensed by said sensing means.

23. In combination; load weighing mechanism, 7 

